CZ279166B6 - Device for igniting a high-pressure discharge lamp in motor vehicles - Google Patents

Abstract

The device is provided with a DC power source (B) connected to an alternating voltage generator (W), with an ignition device (Z) between the AC voltage generator (W) and the high pressure gas discharge lamp (GDL) with the voltage meter (U) and / or current meter. (I) in the lamp circuit (GDL) and the comparator (V), which is connected to the voltage meter (U) and / or current (I) and to the alternator voltage (W). An actual power value determining device (L1) is connected to the current meter (I) and the voltage meter (U) and to the comparator (V), the time-controlled power value determining device (LS) is connected via the lamp-state meter (ST) to the current meter (I). ) and the comparator (V). ŕ

Description

Apparatus for igniting high pressure gas discharge lamps in motor vehicles

Technical field

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a device for igniting a high pressure gas discharge lamp in a motor vehicle having a DC voltage source connected to an AC generator, an ignition device between an AC generator and a high pressure discharge lamp. to a voltage and / or current meter and to an AC generator.

BACKGROUND OF THE INVENTION

German Offenlegungsschrift 37 29 383 relates to a method for igniting a high-pressure gas discharge lamp, which discloses a method for triggering a discharge lamp, in which an alternating voltage is generated from a direct voltage which is fed to the ignition device for igniting the discharge lamp. In the lamp circuit and in the AC generator, voltages are measured which are compared to actual values as actual values and, depending on them, the power supplied to the lamp changes. In order for the lamp to be reliably switched to a stable operating state after ignition, an additional power is supplied to it for a predetermined period of time, depending on the actual value of the measured voltage, along with the operating power by changing the alternating voltage. The change in AC voltage occurs by increasing the pulse duty cycle immediately after ignition of the lamp compared to the pulse duty cycle during operation.

The disadvantage of this method is that a constant additional power is supplied to the high-pressure lamp after ignition, so that the high-pressure lamp, especially in the case of a short break after ignition, can produce too high light output which could lead to glare which is particularly dangerous in motor vehicles. A further disadvantage is that the high-pressure lamp starts with different luminous intensity according to different existing connection conditions, so that the luminous increase of luminous intensity as fast as possible can not be achieved as quickly as possible.

The circuitry includes a DC voltage source that is connected to the AC generator, an ignition device between the AC generator and the lamp, at least one voltage meter in the lamp circuit, and a comparator that energizes the AC generator to vary the AC voltage.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method and apparatus for igniting high pressure gas discharge lamps in a motor vehicle such that it is simple, inexpensive and ensures that the high pressure discharge lamp achieves optimum operating state independently of the connection condition and as quickly as possible. possible evenly monotonically increasing luminous intensity.

-1EN 279166 B6%

SUMMARY OF THE INVENTION

This task is accomplished by a device for igniting a high pressure gas discharge lamp in a motor vehicle, with a direct current source connected to an AC generator, an ignition device between an AC generator and a high pressure gas discharge lamp, a voltage meter and / or current meter in the lamp circuit, which is connected on the one hand to a voltage and / or current meter and, on the other hand, to an AC voltage generator according to the invention, which is based on the fact that the actual power input is connected to the current and voltage meter and the comparator; lamp status indicator with current meter and comparator.

The advantage of connecting the actual power input detector to the voltage meter, current meter and comparator is that it provides a very simple and inexpensive measuring circuit for determining the actual power value.

According to the invention it is advantageous that the power input value has been coupled to the current meter and the comparator, to create a very power input in connecting the power input to the desired voltage, then the AC voltage can easily change to high pressure. power and auxiliary at the times of shutdown and at the time of the last lamp, and compare the actual value by the value so that a signal can be supplied to the AC generator, on the basis of which it is possible to reduce or increase the power consumption.

In this context, it is particularly advantageous if the power setpoint adjuster according to the invention has at least two time members, since in this case additional power may be supplied to the high-pressure lamp depending on the switch-off times and the duration of the last switch-on time; this additional wattage ensures that the high-pressure discharge lamp achieves a stable operating state as quickly as possible and without exceeding the desired luminous intensity independently of the different switching states. The first time member measures the high lamp discharge time, and the second time member last last high lamp discharge time.

In this context, it is particularly advantageous if the power setpoint detector determines, by means of a characteristic field depending on the measured on and off times, the power setpoint taking into account the maximum lamp current, since in this way the optimum lamp operating condition is reliably achieved in every ignition situation , and its optimum start.

According to another embodiment, the power set point detector comprises a first capacitor having blocking members and / or resistors, determining the magnitude of the additional power depending on the shut-off times and the duration of the last switch-on times of the high pressure gas discharge lamp. determining the duration of the additional power, depending on the off times and the last on times.

-2GB 279166 B6

It is advantageous if the actual input of the power input is connected both to the current meter and the voltage meter and to the comparator and the time-controlled input of the desired input power value is connected to the current meter and the comparator via the lamp status indicator. This results in a simple, inexpensive wiring that ensures reliable ignition and operation of the high-pressure discharge lamp, depending on predetermined setpoints and measured power values.

In this context, it is particularly advantageous according to the invention that the power input setter has a first capacitor fitted with blocking members and / or resistors which determines the amount of additional power depending on the shut-off times and the last time the high-pressure discharge lamp is switched on. The power input comprises a second capacitor, also fitted with blocking elements and / or resistors, which determines the duration of the additional power input depending on the trip times and the duration of the last trip time. This ensures reliable ignition of the high-pressure discharge lamp, which achieves an optimal operating state when switched on and without exceeding the required luminance and thus without glare.

Advantageously, the voltage waveform on the first capacitor determines the function of decreasing the additional power input after the time of the additional power input has elapsed: this avoids fluctuations in luminous intensity when the additional power is degraded.

Finally, according to another embodiment of the invention, the lamp conditioner is coupled to a control input of a switching device whose switching path connects either the first reference voltage terminal or ground through a first resistor with a non inverting comparator input is grounded via a second capacitor. the second reference voltage, the comparator output excites a switch whose switching path connects the first reference voltage terminal through the blocking member both through the ninth resistor with the non-inverting input of the ideal voltage monitor and through the eighth resistor with the ground. the voltage monitor is connected through the first capacitor, the output of the voltage monitor is connected to its inverting input and through the fourteenth resistor to the inverting input of the reader whose non-inverting input is connected to the third reference voltage terminal, and that the output of the reader is connected via its thirteenth resistor to its inverting input and to the output connected to the comparator.

Overview of the drawings

Examples of the invention will be described in detail with reference to the accompanying drawings, in which the same or similarly acting circuit elements are indicated by the same reference numerals. FIG. 1 is a block diagram of a high pressure gas discharge lamp ignition device; and Fig. 3 is a power diagram.

DETAILED DESCRIPTION OF THE INVENTION

Figure 1 is a block diagram of an apparatus for igniting a high pressure gas discharge lamp (GDL). The DC voltage source B, which may be a motor vehicle battery, is electrically coupled

-3GB 279166 B6 with an AC generator W that generates an AC voltage from the DC voltage. The generated AC voltage may be controllable to control power input in frequency, pulse width, and pulse height. To ignite the high pressure gas discharge lamp (GDI), the AC generator W is coupled to the ignition device Z. which supplies the high pressure gas discharge lamp (GDL) with ignition voltage and operating voltage during operation.

To determine the power supplied to the high pressure gas discharge lamp (GDL), the wiring includes an actual power input L1 which is connected both to a voltage meter U connected in parallel to the high pressure gas discharge lamp GDL and to a current meter I connected in the lamp circuit. The voltage meter U indicates the voltage value that corresponds to the high pressure gas discharge lamp (GDL) voltage. The current meter I indicates the voltage that corresponds to the current flowing through the lamp circuit. In this case, the actual power input LI can be designed as a multiplier, which by multiplying the input signals produces the actual power input, which is applied as a voltage signal to the comparator V, connected electrically conductively to the AC generator W to control the power. In this case, the comparator V is connected to a power setpoint detector LS, which is connected to the current meter I via a lamp status indicator ST. In this case, the ST status indicator determines the ON state of the lamp when the predetermined current flows in the high pressure gas discharge circuit (GDL), and the OFF state of the lamp when its current drops below a predetermined value.

The comparator V compares the desired power value with the actual power value and produces a voltage signal that is applied to the AC generator W to change the generator AC voltage in terms of power change.

In the operation of a high-pressure gas discharge lamp (GDL), such power regulation has the advantage that the lamp can be regulated in terms of output and hence of luminous intensity and can also be operated under optimal operating conditions.

In particular, when operating high-pressure GDL gas lamps in motor vehicles for road lighting, there is a requirement that the light output delivered by the lamp be achieved as quickly as possible. For this purpose, an additional power can be supplied to the GDL high pressure gas discharge lamp during normal start-up during normal start-up.

In the device according to the invention, this is carried out by determining the power setpoint LS by means of a characteristic field as a function of the measured on and off times, and taking into account the maximum lamp discharge current. In addition, the wiring may comprise a timing element that measures the switch off times of the high pressure gas discharge lamp (GDL). The second wiring timer measures the duration of the last GDL high-pressure gas discharge lamp on-time. In this case, the timers can be excited by the lamp on and off lamp values generated by the lamp status indicator ST. This ensures in a simple and reliable manner that the high-pressure gas discharge lamp GDL ignites and reaches an optimum operating state independently of the previous on or off, quickly and without exceeding the required light output and thus without dazzling the oncoming driver, with uniform monotonically increasing luminous intensity.

-4GB 279166 B6

Giant. 2 shows a simple and inexpensive example of wiring of the power setpoint adjuster LS.

In this connection, the ST status indicator ST is coupled to the control input SE of the switching device S, whose switching path can connect either the UR1 terminal of the first reference voltage or the ground through the first resistor RI to the non inverting comparator input K. second capacitor C2 with ground. The inverting input of comparator K is connected to the second reference voltage terminal UR2. The output of comparator K is connected, for example, to a switch SA whose switching path connects the terminal UR1 of the first reference voltage through the blocking member D, on the one hand through the ninth resistor R9 with the non-inverting input of the ideal voltage monitor SF. The non-inverting input of the voltage monitor SF is coupled to ground through the first capacitor C1.

The output of the voltage monitor SF is connected both to the inverting input of this voltage monitor SF and secondly via the fourteenth resistor R14 with the inverting input of the subtractor SH. The non-inverting input of the subtractor SH is connected via a thirteenth resistor R13 to the inverting input of this subtractor SH and to the input A connected to comparator V.

Based on the diagram in Fig. 3, the method of igniting a lamp will be described in the following.

In the diagram of FIG. 3, the abscissa axis is a timeline denoted by t, and the ordinate axis is a power input L. For a high pressure gas discharge lamp (GDL), a power input BL having a constant or variable value is required for optimal operation. After ignition of the high-pressure gas discharge lamp (GDL), in addition to the operating power BL, the additional power ZL is supplied to it for fast and reliable start-up. The amount of additional power input ZL varies between 0 and the maximum additional power input ZLM, depending on the switch-off times and the duration of the last switch-on times of the high-pressure gas discharge lamp (GDL). The time T of the additional power input ZL varies between zero and the maximum time TM of operation, depending on the trip times and the duration of the last on times. For example, during the time T of the additional power input ZL, the additional power input ZL acquires a constant value. As a result of the maximum allowable inrush current, the discharge power of the lamp immediately after ignition is additionally limited, as shown in FIG. 3. For example, the additional power input ZL decreases down to the operating power BL after the time T has elapsed. This produces a set of curves that represent a field of characteristics that depends on the switch-off times and the last switch-on times of the high-pressure GDL gas discharge lamp. These curves can be measured or calculated. The additional power ZL to be generated increases with increasing switch-off time and decreasing last-on-duration time, and the time T of additional power input ZL increases with increasing switch-off time and decreasing last-on duration of the high-pressure discharge lamp GDL.

As described with reference to FIG. 1, such a characteristic field can be recorded in the characteristic memory in the LS setpoint adjuster. In this case, this power setpoint adjuster LS may comprise a first timing element which measures the time of the lamp state ST according to the state values

-5GB 279166 B6 Switching off the GDL high pressure gas discharge lamp after the last switch-off until the next ignition. The second timing element can measure the duration of the last on-time of the high pressure gas discharge lamp (GDL), depending on the state values and the ST status indicator ST. Depending on the signals from the first and second timers, the AC generator W generates additional power ZL according to the characteristic field.

When the high pressure GDL gas lamp has been out of service for a long time and is therefore cold, the maximum additional power of the ZLM is delivered to it. Otherwise, when the operation of the high-pressure gas discharge lamp (GDL) has been interrupted only for a short time and the duration of the last switch-on was very long, only the operating power BL is supplied to the high-pressure gas discharge lamp (GDL). The curves shown in Fig. 3 are to be considered as examples only: in other embodiments, the constant waveform of additional power ZL during the time T of the additional power input may be replaced by a waveform adapted to the operating conditions of the high pressure gas discharge lamp GDL.

In the following, FIG. 2 is described in detail.

wiring function according to

The high-pressure gas discharge lamp is actuated at time t = 0 and the first reference voltage UR1 is connected via the switching device S to the power setpoint detector LS. At time t = 0, the capacitors are de-energized and all three reference voltages UR1, UR2 and UR3 are rated. The required voltage US at the output A of the subtractor SH corresponds at this time to the maximum power demand and is equal to

US = UR3. (1 + R 13 / R 14), where is

US - voltage setpoint

UR3 - third reference voltage value

R13 - value of thirteenth resistance R13

R14 - value of the fourteenth resistance R14.

The second capacitor C2 is charged through the first resistor R1 and the first time constant T1 = R1. Cl. When the voltage at this second capacitor C2 reaches the value of the second reference voltage UR2, comparator K connects the switch SA and the first capacitor C1 is charged via the ninth resistor R9, via the blocking member D, through the first reference voltage terminal UR1 with the second time constant T2 - R9. Cl. Thus, the required voltage US at output A is reduced to a value

US (t) = UR 3 (1 + R 13 / R 14) - UCl (t) R 13 / R 14.

UCl (t) indicates the time change on the first capacitor C1 and US (t) describes the time change of the desired voltage US, which corresponds to the desired power value. When the first capacitor C1 is charged to the value of the first reference voltage UR1, then the power demand setpoint corresponds to that of the first reference voltage. voltage setpoint US, operating power BL:

-6GB 279166 B6

US = UR3. (1 + R13 / R14) - UR1. R13 / R14.

When the high pressure gas discharge lamp GDL is switched off at t1> 0, the switch S is connected to ground and the second capacitor C2 is discharged via a first resistor R1 with a first time constant T1. The first capacitor C1 discharges through the eighth resistor R8 and the ninth resistor R9 with the third time constant T3, which is given by the expression T3 = (R8 + R9) .Cl.

When the high pressure gas discharge lamp (GDL) is switched on again at time t2> t1, the above waveform is influenced by the residual voltage on the first capacitor C1 and on the second capacitor C2. The residual voltage at the first capacitor C1 determines the amount of additional power ZL and the residual voltage at the second capacitor C2 the duration of the additional power ZL.

Claims (4)

1. Apparatus for igniting a high pressure gas discharge lamp in a motor vehicle, with a direct current source connected to an AC generator, with an ignition device between the AC generator and the high pressure gas discharge lamp, a voltage meter and / or current meter in the lamp circuit and a comparator is connected both to a voltage and / or current meter and to an alternating voltage generator, characterized in that the current meter (L1) of the actual power input, time controlled, is connected to the current meter (I) and voltage meter (U) and the power input setpoint indicator (LS) is coupled to the current converter (I) and the comparator (V) via the lamp state determination (ST). Apparatus according to claim 1, characterized in that the power input set point (LS) comprises at least two time elements. Apparatus according to claim 1, characterized in that the power setpoint detector (LS) comprises a first capacitor (C1) with blocking members and / or resistors, determining the high pressure gas discharge lamp (GDL) as a function of the switch-off times and the last switch-on times. the additional power input and the desired power input (LS) includes a second capacitor (C2) with interlocking members and / or resistors determining, depending on the off times and the last on times, the additional power input time. Apparatus according to claim 3, characterized in that the lamp status detector (ST) is connected to the control input (SE) of the switching device (S), the switching path of which connects either the first reference voltage terminal (UR1) or ground through the first resistor. (R1) with non-inverting comparator input (K) that they do not invert The comparator input (K) is grounded through the second capacitor (C2), the inverting comparator input (K) is connected to the second reference voltage terminal (UR2), the comparator output (K) is connected to the control input of the switch (SA) whose switching path connects through the blocking member (D) the first reference voltage terminal (UR1) both through the ninth resistor (R9) with the non-inverting input of the ideal voltage monitor (SF) and through the eighth resistor (R8) with the non-inverting voltage input (SF) is grounded through the first capacitor (Cl), the output of the voltage monitor (SF) is connected to its inverting input and through the 14th resistor (R14) to the inverting input of the counter (SH), whose non-inverting input is connected to the third reference terminal voltage (UR3), and that the output of the reader (SH) is connected via its thirteenth resistor (R13) to its inverting input and to the output (A) connected to dresser (V).